KTH MoveAbility Lab, Department of Engineering Mechanics, Royal Institute of Technology, Stockholm, Sweden.
KTH BioMEx Center, Royal Institute of Technology, Stockholm, Sweden.
Biomed Res Int. 2021 Feb 9;2021:8899699. doi: 10.1155/2021/8899699. eCollection 2021.
The characterization of the passive mechanical properties of the human triceps surae musculotendinous unit is important for gaining a deeper understanding of the interactive responses of the tendon and muscle tissues to loading during passive stretching. This study sought to quantify a comprehensive set of passive muscle-tendon properties such as slack length, stiffness, and the stress-strain relationship using a combination of ultrasound imaging and a three-dimensional motion capture system in healthy adults. By measuring tendon length, the cross-section areas of the Achilles tendon subcompartments (i.e., medial gastrocnemius and soleus aspects), and the ankle torque simultaneously, the mechanical properties of each individual compartment can be specifically identified. We found that the medial gastrocnemius (GM) and soleus (SOL) aspects of the Achilles tendon have similar mechanical properties in terms of slack angle (GM: -10.96° ± 3.48°; SOL: -8.50° ± 4.03°), moment arm at 0° of ankle angle (GM: 30.35 ± 6.42 mm; SOL: 31.39 ± 6.42 mm), and stiffness (GM: 23.18 ± 13.46 Nmm; SOL: 31.57 ± 13.26 Nmm). However, maximal tendon stress in the GM was significantly less than that in SOL (GM: 2.96 ± 1.50 MPa; SOL: 4.90 ± 1.88 MPa, = 0.024), largely due to the higher passive force observed in the soleus compartment (GM: 99.89 ± 39.50 N; SOL: 174.59 ± 79.54 N, = 0.020). Moreover, the tendon contributed to more than half of the total muscle-tendon unit lengthening during the passive stretch. This unequal passive stress between the medial gastrocnemius and the soleus tendon might contribute to the asymmetrical loading and deformation of the Achilles tendon during motion reported in the literature. Such information is relevant to understanding the Achilles tendon function and loading profile in pathological populations in the future.
人类跟腱肌腹肌腱单元的被动力学特性的特征对于深入了解肌腱和肌肉组织在被动拉伸过程中对加载的相互响应非常重要。本研究旨在使用超声成像和三维运动捕捉系统相结合的方法,在健康成年人中量化一系列全面的被动肌肉-肌腱特性,如松弛长度、刚度和应力-应变关系。通过测量跟腱长度、跟腱亚部(即内侧腓肠肌和比目鱼肌)的横截面积以及踝关节扭矩,可特异性识别每个单独隔间的机械特性。我们发现,跟腱的内侧腓肠肌(GM)和比目鱼肌(SOL)方面在松弛角度(GM:-10.96°±3.48°;SOL:-8.50°±4.03°)、踝关节角度为 0°时的力臂(GM:30.35±6.42mm;SOL:31.39±6.42mm)和刚度(GM:23.18±13.46Nmm;SOL:31.57±13.26Nmm)方面具有相似的机械特性。然而,GM 中的最大肌腱应力明显小于 SOL(GM:2.96±1.50MPa;SOL:4.90±1.88MPa, = 0.024),这主要是由于比目鱼肌隔间中观察到的被动力较高(GM:99.89±39.50N;SOL:174.59±79.54N, = 0.020)。此外,在被动拉伸过程中,肌腱贡献了超过一半的整个肌腹肌腱单元的伸长。内侧腓肠肌和比目鱼肌腱之间这种不均匀的被动应力可能导致文献中报道的跟腱在运动中出现不对称的加载和变形。这些信息对于未来理解病理人群中跟腱的功能和加载情况具有重要意义。
